Origami-Inspired Structure with Pneumatic-Induced Variable Stiffness for Multi-DOF Force-Sensing

Yue, Wenchao; Qi, Jiaming; Song, Xiao; Fan, Shicheng; Fortino, Giancarlo; Chen, Chia-Hung; Xu, Chen; Ren, Hongliang

doi:10.3390/s22145370

Cited by 10 publications

(11 citation statements)

References 34 publications

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“…• Molding: Much like lamination, this process involves making a mold that can accept various materials to create a part that has a mixture of properties. The mold itself can be made from inexpensive processes like 3D printing, and the mold can accept a wide range of materials from silicon to ethylene-vinyl acetate copolymer (EVA) [39], and even cardboard [40]. The advantage of this process is that it is cost-effective and easily executable without specialized equipment, while being able to make a material that combines properties from the original sub-materials.…”

Section: ) Pre-folding Fabrication Tools and Methodsmentioning

confidence: 99%

Origami-Inspired Haptics: A Literature Review

Iiyoshi,

Lee,

Dalaq

et al. 2024

IEEE Access

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Origami, the art of paper folding, addresses traditionally conflicting requirements for designing both powerful and low-cost haptic interfaces. As of today, there are no comprehensive reviews that cover origami-inspired haptic actuation, sensing, design processes, and fabrication. To fill this void, this paper summarizes existing origami-inspired haptic technologies in terms of workspace, degrees of freedom (DoF), power consumption, control methods, sensing, and actuation. The paper also presents an iterative design process for pattern generation and origami-inspired haptic characterization. Using this design process, we demonstrate a case study that involves the design, development, and evaluation of a novel syringe haptic interface for dental simulation. Our main findings suggest that origami-inspired haptics need more mathematically optimized and versatile design, as well as novel materials that offer a room for embedded sensing and actuation.

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Section: ) Pre-folding Fabrication Tools and Methodsmentioning

confidence: 99%

Origami-Inspired Haptics: A Literature Review

Iiyoshi,

Lee,

Dalaq

et al. 2024

IEEE Access

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“…The complex configurations and overall shapes of 2D materials, hinges, bonding sites, and cut patterns dictate the features of origami-and kirigami-inspired 3D structures. [109][110][111] Highly complex and on-demand shapes can be developed using origami and kirigami techniques. [109][110][111] The degree of complexity of these structures is higher than that of the structures formed following folding and buckling techniques.…”

Section: Origami-and Kirigami-inspired 3d Structuresmentioning

confidence: 99%

“…[109][110][111] Highly complex and on-demand shapes can be developed using origami and kirigami techniques. [109][110][111] The degree of complexity of these structures is higher than that of the structures formed following folding and buckling techniques. Research works on origami-and kirigami-based structures focus on two directions: 1) The enhancement of stability of complex 3D shapes and 2) achieving high-level design complexity.…”

Section: Origami-and Kirigami-inspired 3d Structuresmentioning

confidence: 99%

3D Electronic Sensors for Bio‐Interfaced Electronics and Soft Robotics

Gu¹,

Lee²,

Kang³

2023

Advanced Sensor Research

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Multi‐dimensional electronic devices for sensing applications have received immense attention in the fields of bio‐interface electronics and soft robotics to achieve structural manifolds in recent years. The structural diversities of sensors are tuned based on the environments in which they encounter multipurpose and complex form factors of electronics. 3D electronics are one of the emerging sensor platforms characterized by structural adaptability and compatibility on free target surfaces, resulting in unprecedented improvement of spatial resolution. Herein, the recent progress made in the fabrication and usage of 3D electronic sensors that are classified into two groups based on the methodological concepts used for fabrication in bio‐interfaced electronics and soft robotics applications, is reviewed. The latest advances in the design and development of 3D printable and 2D to 3D shape‐deformable electronic sensors are reviewed with a focus on printable materials and deformation mechanisms, respectively. 3D printing techniques enable the facile fabrication of arbitrary and seamless electronics without the use of conventional microfabrication technologies. Deformable electronics cover their self‐tune architectures and functions depending on mechanical deformation based on buckling, origami, and kirigami fabrication strategies. Finally, the printed and deformable 3D sensors show their potential for use in next‐generation sensing platforms.

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“…[5][6][7][8] Therefore, compared to traditional rigid-body robotics, soft robotics shows excellent potential for various application scenes, including the medical field, search and rescue detection, industry manipulation, educational demonstration, etc. [9][10][11][12][13][14][15] It is worth mentioning that soft actuators play an essential role in promoting soft robotics development. [16][17][18] Soft pneumatic actuators typically mimic the structure of human muscle units, i.e., bionic artificial muscles, which can realize expansion and deflation through inner pressure; meanwhile, specific constraints are applied to the structure to achieve linear and angular motion.…”

Section: Introductionmentioning

confidence: 99%

“…[ 5–8 ] Therefore, compared to traditional rigid‐body robotics, soft robotics shows excellent potential for various application scenes, including the medical field, search and rescue detection, industry manipulation, educational demonstration, etc. [ 9–15 ]…”

Section: Introductionmentioning

confidence: 99%

Dual‐Stroke Soft Peltier Pouch Motor Based on Pipeless Thermo‐Pneumatic Actuation

Yue,

Bai,

Lai

et al. 2023

Adv Eng Mater

Self Cite

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Soft pneumatic actuators are made of flexible materials that deform in response to pressure changes. Due to their reliability, safety, and flexibility, such actuators enable diverse hardware design and become indispensable for soft robots. However, bulky air compressors and pipes constrain their further integration and lightweight. The liquid–vapor phase transition can produce significant encapsulated volume changes and achieve pipeless thermo‐pneumatic actuation. Herein, a novel soft thermoelectric‐based actuator, named Peltier pouch motor (PPM), is presented with modular and dual‐stroke characteristics enabled by active phase transition of low‐boiling‐point liquid. Furthermore, its lightweight and stretchable compliance contributes to assembly‐induced hyper‐modularity to create diverse degrees‐of‐freedom hybrid systems. Finally, the various forms of PPM units are exploited and versatile locomotion is facilitated for five different applications under multi‐medium scenarios, including thermo‐responsive land locomotion, submersible noise‐free hovering, smart curtains control, body‐temperature‐driven wrist rehabilitation, and adaptive hybrid gripper. In these results, it is indicated that the proposed PPM unit advances in hyper‐modularity with excellent performance in high load rate (around 400%), heat transfer efficiency (heating boost, 425%; cooling boost, 138%), and thermal response performance (heating, 0.57° s−1; cooling, 0.29° s−1; 4.5 V), inspiring widely innovative soft robots through the pipeless thermo‐pneumatic actuation.

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Origami-Inspired Structure with Pneumatic-Induced Variable Stiffness for Multi-DOF Force-Sensing

Cited by 10 publications

References 34 publications

Origami-Inspired Haptics: A Literature Review

Origami-Inspired Haptics: A Literature Review

3D Electronic Sensors for Bio‐Interfaced Electronics and Soft Robotics

Dual‐Stroke Soft Peltier Pouch Motor Based on Pipeless Thermo‐Pneumatic Actuation

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